DE3126207C2 - Timed ventilator - Google Patents

Abstract

The ventilator for use in pressure chambers is used to ventilate patients in therapy or diving pressure chambers. All of its functions are pneumatic. The ventilator must always deliver the selected a) ventilation volume (in operating liters) independently of the chamber pressure and maintain the selected b) breathing frequency. To fulfill a) the ventilator has a known pressure ratio regulator based on the double membrane principle and for b) a frequency constant. The frequency constant contains a stepped piston in a housing that is moved by the chamber pressure against a spring, forming two volumes. The ratio of the free piston areas to one another determines the breathing time ratio. The volume set by the chamber pressure via the altitude, together with the gas volume / time unit set by a precision control valve, determine the breathing frequency. A changing chamber pressure has no effect on the breathing time ratio and the breathing frequency. The ventilator is suitable for use in therapy pressure chambers such as oxygen pressure chambers and diving pressure chambers.

Description

The invention relates to a time-controlled ventilator according to the generic term of claim 1.

The use of z. B. pressure chambers to therapeutic Purposes or the need for medical care in environments with changing pressure requires medical and thus also ventilators that can be used under this. The known ones here The fully pneumatic ventilators used are dependent on the ambient pressure. The one at atmospheric pressure Change the set ventilation parameters such as minute ventilation (MV) and the breathing rate with the ambient pressure. Continuous readjustment is then necessary when the pressure changes.

A known ventilator, especially for small children, switches the inhalation and exhalation phases by controlling the exhalation valve from a timing system made up of pneumatic components. The pressure of the breathing gas supplied to the device via a filter is reduced in a pressure reducer reduced to the operating pressure. This serves on the one hand to supply the patient, on the other hand the operation of the timing system. The breathing gas is supplied to the patient via a flow valve and then released into the environment via the exhalation valve controlled by the time control system. That Time control system is made up of pneumatic logic elements that are switched in the form of two chains and at the end of which are connected to form a bistable switch. Each chain determines the duration of a Breathing phase. For this purpose, a volume is switched on in each chain, which together with one each is in the Gas supply of the chain is switched on fine control valve forms a FLC link. After charging the respective volume to a switching pressure of 80% of the operating pressure takes place with the switch to the other chain switching to the other breathing phase and at the same time venting the charged one Volume.

For use under changing ambient pressures this ventilator is not suitable. B. increasing pressure suffices the breathing gas supply not from. It must be running on the flow valve

to be readjusted. In addition, higher ambient pressures cause the breathing rate control to switch faster. Here, too, continuous adjustment is required (DE-OS 28 01 546).
Another ventilator, from which the above device according to DE-OS 28 01 546 had taken over essential ideas, has a time control system made up of pneumatic components with which a main valve in the breathing gas line and the exhalation valve are switched according to the inhalation and exhalation phases.

With a gas volume regulator in the breathing gas line behind the main valve, the breathing gas volume is then set regulated The inhalation and exhalation phases are controlled via a 1st upstream double diaphragm valve by a control with a bistable flip-flop, which in a first branch 'via a

2. Double diaphragm valve and a 1. volume for specifying the inhalation time and in a second branch via a

3rd double diaphragm valve and a 2nd volume for specifying the exhalation time is controlled. Also takes place here after the respective volume has been charged to a switching pressure of 80% of the operating pressure, the switchover on the other breathing phase.

Changing ambient pressures around the ventilator also change the amount of breathing gas here as well also the breathing rate accordingly (DE-OS 27 46 924).

The object of the invention is a time-controlled

Ventilator whose ventilation parameters respiratory

* Volume and breathing rate remain constant when the ambient pressure changes, readjustments should not be necessary.

The object is achieved according to the characterizing part of claim 1. Advantageous developments are described in claims 2 and 3.
Using the

a) Pressure ratio regulator, working according to the double membrane principle, secures in a technically easier way and in a proven way for the patient to be treated, a current from the ambient pressure independent exact supply of breathing gas. The supply takes place with the once set Amount, d. H. the amount in operating units always remains the same regardless of the ambient pressure.

The same applies to the inhalation and exhalation times each other and the respiratory rate. Of the

b) Frequency constant with its simple mechanical structure, which is essentially due to the graduated piston, which forms the two volumes, ensures even with changing ambient pressures for an equal breathing rate.

The object of the invention is achieved by

a) the pressure ratio regulator together with

b) solved the frequency constant in a clear and excellent manner

The ventilator is also suitable for use in therapy pressure chambers, such as B. Oxygen hyperbaric chambers as well as suitable for use in diving pressure chambers

An embodiment of the invention is shown in the drawing and is described below. It shows

F i g. 1 the ventilator in a schematic representation within a pressure chamber,

F i g. 2 the frequency constant,

F i g. 3 the pressure ratio regulator.

The ventilator set up inside a pressure chamber 1 is supplied with a ventilator outside the pressure chamber 1 located gas supply at connection 2 breathing gas is supplied. From there »it succeeded through a filter 3, a main switch 4 and a main valve 6 actuated by a timing control 5, a pressure ratio regulator 7, a manually adjustable flow valve 9 to the patient, symbolized by the elastic, volume 10 is shown. A pressure limiter 11 and a pressure limiter are attached to the breathing gas line in the vicinity of the patient Pressure indicator 12 connected. The exhalation valve 13 is actuated by the time control 5 Exhaled gas at 14 the ventilator into the pressure chamber 1.

The time control 5 is connected to the breathing gas line via a pressure reducer 15 το behind the main switch 4. From the outlet of the pressure reducer 15 are connected via a line 16, a flip-flop 17 and a precision control valve 18, two double-diaphragm valves 19, 20 with breathing gas as propellant gas supplied The double diaphragm valves 19, 20 are each a volume A 21 and

5 22, which are inside a frequency constant 23, connected to the inputs of the flip-flop 17. The outputs 26,27 of the flip-flop 17 control the main valve

6 and the exhalation valve 13 and simultaneously effect a switchover of the double diaphragm valves 19, 20. This results in the following sequence:

During the inhalation phase, the output 27 of the flip-flop 17 is connected to the line 16 and carries the operating pressure required for the time control 5, ie a 1 signal; Output 26 carries the 0 signal. As a result, the main valve 6 is opened and the exhalation valve 13 is closed. The double diaphragm valve 20 is vented, the volume 522 in the closed position in which the interior of the D ^r uckkammer. 1 The double diaphragm valve 19 is open and allows a gas flow set on the precision control valve 18 to enter the volume A 21. This charging increases the pressure in volume A 21. When it reaches a switching pressure of 80% of the operating pressure, it triggers the switchover of the flip-flop 17 at the input of the flip-flop 17 and thus the change in the breathing phase.

During the exhalation phase, output 27 of flip-flop 17 has a 0 signal and output 26 has a 1 signal. The main valve 6 is closed, the exhalation valve 13 is open. The processes proceed in the same way as described for the inhalation phase, ie volume A 21 is vented via the double diaphragm valve 19, and volume 522 is charged via the opened double diaphragm valve 20. After the switching pressure has been reached, there is a change to the inhalation phase.

The frequency constant 23 according to FIG. 2 contains a piston 29 in a housing 28 which can be rotated three graduated diameters. The upper part of the piston

30 closes with its end face opposite the housing 28, the volume A 21, the middle piston part

31 the annular volume .822 and the lower piston part 32 the chamber 33. The chamber 33 is connected to the interior of the pressure chamber 1 via an opening 24. Below the piston 29, the housing 28 forms a closed spring chamber 34 which is connected to the atmosphere outside the pressure chamber 1 via a connection 25 the end wall of the spring chamber 34 can be adjusted. An adjustable stop 37 in the chamber 33 limits the stroke of the piston Ta. The volume A 21 is connected to the flip-flop 17 and the double diaphragm valve 19 via the connection opening 38, the volume B 22 via the connection opening 39 to the flip-flop 17 and the double diaphragm valve 20 .

If the pressure in the pressure chamber 1 corresponds to the pressure of the surrounding atmosphere, the large piston part 32 rests against the stop 37 when the spring 35 is relaxed, and the volumes A 21 and 522 have their minimum size. They are then alternately filled up to a switching pressure

The time required to fill the respective volume determines the duration of the associated Breathing phase. The predetermined ratio of the cross-sectional area of the upper 30 and the annular area of the middle piston part 31 determines the breathing time ratio, which is also with an axial adjustment of the Piston 29 does not change

The setting of the fine control valve 18 results the time required to charge the volumes Λ 21 and S 22 and thus the ventilation frequency.

So that with increasing pressure in the pressure chamber 1 and unchanged setting of the fine control valve 18 there is no shortening of the filling times of the volumes AIv and 522 and thus an increase in the ventilation frequency, the size of the volumes A 21 and 522 is increased accordingly by moving the piston 29 the chamber pressure axially exerted on the piston 29 in the chamber 33 and in the volumes A 21 and 522, which displaces the piston 29 against the force of the spring 35.

The pressure ratio regulator 7 according to Figure 3 contains a large membrane 41 and a housing 40 small membrane 42. They are coupled together in the middle by a bolt 43 and with a Outside the small membrane 42 located Vrntiucürper 44 connected. The valve body 44 forms with its seat 45 a valve. A pressure chamber 46 covering the valve body 44 is created. Breathing gas fed through a terminal 47. A back pressure space 48 between the seat 45 and the small diaphragm 42 is connected to the flow valve; l 9. A space 49 between the membranes 41, 42 is connected to the atmosphere outside the pressure chamber 1 via the connection 8. One outside the big one Diaphragm 41 located spring chamber 50 contains a compression spring 51 and is via an opening 52 with the Pressure in the pressure chamber 1 connected. When the breathing gas supply is closed, the valve body 44 is from the seat 45 lifted.

The pressure ratio regulator 7 ensures the same for the patient to be ventilated under all chamber pressures Ventilation volume. He gets one in liters

the same amount of breathing gas for all chamber pressures.

When the chamber pressure increases, the difference in area between the membranes 41, 42 opens the valve 44, 45 and lets the breathing air flow in under higher pressure. The flow conditions change proportionally to Pressure change.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Time-controlled ventilator with a control system made up of pneumatic components for the Clock ratio and the cycle time of the inhalation and exhalation phase using two specified volumes as time-determining members of a pneumatic oscillator arrangement, of which control a main valve in the breathing gas line and the exhalation valve is switched according to the inhalation and exhalation phase and with a gas flow regulator in the breathing gas line behind the main valve, characterized in that the gas volume regulator is a pressure ratio regulator (7) according to the double membrane principle, and that the two volumes (21,22) as pressure chambers between a stepped piston (29) and a correspondingly geffc 3iten cylinder (28) are formed, wherein the piston (29) is biased against the chamber pressure by a spring (35) 2. Time-controlled ventilator according to claim 1, characterized in that the spring (35) can be changed in the free length by means of an adjusting screw (36) in the bottom of the housing (28) can. 3. Time-controlled ventilator according to claim 1 and 2, characterized in that a adjustable stop (37) the path of the stepped piston (29). the two volumes (21, 22) after the Determining minimum size, limited